A split-gate MOSFET includes first and second epitaxial layers, first, second, and third gates, a gate oxide layer, a trench oxide layer, and a trench implantation region formed on a substrate in order. The second epitaxial layer has a doping concentration greater than that of the first epitaxial layer. A plurality of trenches is in the first and second epitaxial layers. Both the first and second gates are located in each of the trenches in a cell region. The third gates are located in each of the trenches in a terminal region. The third gate closest to the cell region is grounded, and the others are floating. The gate oxide layer is disposed between the first and second gates. The trench oxide layer is located between the first gate and the first epitaxial layer and located between the trench surface and the third gate. The trench implantation region is located in the first epitaxial layer at the bottom of the trench and has a doping concentration less than that of the first epitaxial layer.

A trench MOSFET with closed cell layout having shielded gate is disclosed, wherein closed gate trenches surrounding a deep trench in each unit cell and the shielded gate disposed in the deep trench. Trenched source-body contacts are formed between the closed gate trenches and the deep trench. The deep trench has square, rectangular, circle or hexagon shape.

This invention discloses a new switching device supported on a semiconductor that includes a drain disposed on a first surface and a source region disposed near a second surface of said semiconductor opposite the first surface. The switching device further includes an insulated gate electrode disposed on top of the second surface for controlling a source to drain current. The switching device further includes a source electrode interposed into the insulated gate electrode for substantially preventing a coupling of an electrical field between the gate electrode and an epitaxial region underneath the insulated gate electrode. The source electrode further covers and extends over the insulated gate for covering an area on the second surface of the semiconductor to contact the source region. The semiconductor substrate further includes an epitaxial layer disposed above and having a different dopant concentration than the drain region. The insulated gate electrode further includes an insulation layer for insulating the gate electrode from the source electrode wherein the insulation layer having a thickness depending on a Vgsmax rating of the vertical power device.

The invention relates to a vertically structured power transistor, such as a VD-MOS or an IGBT, having a cell comprising: two symmetrical source layers (308), preferably N+ doped, which extend from a front surface (312) of the semiconductor substrate; a well layer (307), preferably P doped, comprising an area having a higher doping concentration (307b) that extends from one source layer to the other; a source/well NP junction (J3) between the source layer and the well layer. According to the invention, a cathode formed on the front surface (312) of the semiconductor substrate has a trench portion (309) with a bottom (313) that extends into the area having a higher doping concentration (307b) of the well layer (307) to a certain depth away from the source/well NP junction (J3).

A field effect transistor includes a substrate, an epitaxial layer, a remnant-oxide layer, an electrode, a surrounding-oxide layer, a surrounding-nitride layer, a gate oxide layer, a gate, a P-body region, a source region, an interlayer dielectric and a source electrode. The epitaxial layer on the substrate has a trench having a sidewall and a bottom. The electrode inside the trench is coated subsequently by the surrounding-oxide layer, the surrounding-nitride layer and the remnant-oxide layer. The gate formed on the gate oxide layer is separated from the electrode sequentially by the gate oxide layer, the surrounding-nitride layer and the surrounding-oxide layer. The P-body region and the source region, formed at the epitaxial layer, are separated from the gate by the gate oxide layer. The interlayer dielectric covers the source region and the gate. The source electrode covers the P-body region and the interlayer dielectric, and contacts the source region.

A semiconductor device according to the present invention includes a semiconductor layer, a gate trench defined in the semiconductor layer, a first insulating film arranged on the inner surface of the gate trench, a gate electrode arranged in the gate trench via the first insulating film, and a source layer, a body layer, and a drain layer arranged laterally to the gate trench, in which the first insulating film includes, at least at the bottom of the gate trench, a first portion and a second portion with a film elaborateness lower than that of the first portion from the inner surface of the gate trench in the film thickness direction.

The disclosed technology generally relates to semiconductor devices, and more particularly to a static random access memory (SRAM) having vertical channel transistors and methods of forming the same. In an aspect, a semiconductor device includes a semiconductor substrate and a semiconductor bottom electrode region formed on the substrate and including a first region, a second region and a third region arranged side-by-side. The second region is arranged between the first and the third regions. A first vertical channel transistor, a second vertical channel transistor and a third vertical channel transistor are arranged on the first region, the second region and the third region, respectively. The first, second and third regions are doped such that a first p-n junction is formed between the first and the second regions and a second p-n junction is formed between the second and third regions. A connection region is formed in the bottom electrode region underneath the first, second and third regions, wherein the connection region and the first and third regions are doped with a dopant of a same type. A resistance of a path extending between the first and the third regions through the connection region is lower than a resistance of a path extending between the first and the third regions through the second region. A second aspect is a method of forming the semiconductor device of the first aspect.

In an insulated-gate type semiconductor device in which a gate-purpose conductive layer is embedded into a trench which is formed in a semiconductor substrate, and a source-purpose conductive layer is provided on a major surface of the semiconductor substrate, a portion of a gate pillar which is constituted by both the gate-purpose conductive layer and a cap insulating film for capping an upper surface of the gate-purpose conductive layer is projected from the major surface of the semiconductor substrate; a side wall spacer is provided on a side wall of the projected portion of the gate pillar; and the source-purpose conductive layer is connected to a contact region of the major surface of the semiconductor substrate, which is defined by the side wall spacer.

A semiconductor device includes a source metallization, a source region of a first conductivity type in contact with the source metallization, a body region of a second conductivity type which is adjacent to the source region. The semiconductor device further includes a first field-effect structure including a first insulated gate electrode and a second field-effect structure including a second insulated gate electrode which is electrically connected to the source metallization. The capacitance per unit area between the second insulated gate electrode and the body region is larger than the capacitance per unit area between the first insulated gate electrode and the body region.

A semiconductor device includes a substrate, an active gate trench in the substrate; a source polysilicon pickup trench in the substrate; a polysilicon electrode disposed in the source polysilicon pickup trench; and a body region in the substrate. The top surface of the polysilicon electrode is below the bottom of the body region.